Visuomotor adaptation needs a validation of prediction error by feedback error

Gaveau, Valérie; Prablanc, Claude; Laurent, Damien; Rossetti, Yves; Priot, Anne-Emmanuelle

doi:10.3389/fnhum.2014.00880

Cited by 27 publications

(23 citation statements)

References 99 publications

(180 reference statements)

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“…Such implicit adaptation occurs even when prisms introduce large rotations, so that participants are aware of the exposure [58,59]. It also occurs when terminal visual feedback is applied [60] or when continuous feedback is applied only in the last portion of reaching [61]. These observations seem to contradict the current results, where adaptive changes under terminal feedback were primarily through explicit learning.…”

Section: Discussioncontrasting

confidence: 61%

“…Different visuomotor processes underlying reaching between natural and tool-use settings were revealed recently [49,62,63]. Moreover, the current task required controls of both the hand’s initial trajectory direction and stopping at the target, whereas prism adaptations often require mainly the control of the hand’s initial trajectory direction, such as throwing a ball [59] or rapid pointing being mechanically stopped as the finger lands on the target [60]. Taken together, the sensorimotor processing required for learning the current task was more complex than in the case of prism adaptations, thereby making it difficult to create an internal model of the applied rotation, in turn attenuating implicit adaptation.…”

Section: Discussionmentioning

confidence: 99%

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Eye-Hand Coordination during Visuomotor Adaptation with Different Rotation Angles: Effects of Terminal Visual Feedback

Rand

Rentsch

2016

PLoS ONE

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This study examined adaptive changes of eye-hand coordination during a visuomotor rotation task under the use of terminal visual feedback. Young adults made reaching movements to targets on a digitizer while looking at targets on a monitor where the rotated feedback (a cursor) of hand movements appeared after each movement. Three rotation angles (30°, 75° and 150°) were examined in three groups in order to vary the task difficulty. The results showed that the 30° group gradually reduced direction errors of reaching with practice and adapted well to the visuomotor rotation. The 75° group made large direction errors of reaching, and the 150° group applied a 180° reversal shift from early practice. The 75°and 150° groups, however, overcompensated the respective rotations at the end of practice. Despite these group differences in adaptive changes of reaching, all groups gradually adapted gaze directions prior to reaching from the target area to the areas related to the final positions of reaching during the course of practice. The adaptive changes of both hand and eye movements in all groups mainly reflected adjustments of movement directions based on explicit knowledge of the applied rotation acquired through practice. Only the 30° group showed small implicit adaptation in both effectors. The results suggest that by adapting gaze directions from the target to the final position of reaching based on explicit knowledge of the visuomotor rotation, the oculomotor system supports the limb-motor system to make precise preplanned adjustments of reaching directions during learning of visuomotor rotation under terminal visual feedback.

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Section: Discussioncontrasting

confidence: 61%

Section: Discussionmentioning

confidence: 99%

Eye-Hand Coordination during Visuomotor Adaptation with Different Rotation Angles: Effects of Terminal Visual Feedback

Rand

Rentsch

2016

PLoS ONE

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“…Fourth, our results of condition 4 show that participants exhibited the drift without target error feedback. This result is in line with previous studies showing visuomotor adaptation without explicit targets 9, 10 ; but see 23 . Fifth, despite large differences in performance during adaptation between conditions with and without PE1 available, there was no difference between conditions in delayed washout, with a remarkable superimposition of the decay in washout across conditions.…”

Section: Discussionsupporting

confidence: 94%

Sensory prediction errors, not performance errors, update memories in visuomotor adaptation

Lee

Izawa

et al. 2018

Preprint

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Sensory prediction errors are thought to update memories in motor adaptation, but the role of 1 performance errors is largely unknown. To dissociate these errors, we manipulated visual 2 feedback during fast shooting movements under visuomotor rotation. Participants were 3 instructed to strategically correct for performance errors by shooting to a neighboring target in 4 one of four conditions: following the movement onset, the main target, the neighboring target, 5 both targets, or none of the targets disappeared. Participants in all conditions experienced a drift 6 away from the main target following the strategy. In conditions where the main target was shown, 7 participants often tried to minimize performance errors caused by the drift by generating 8 corrective movements. However, despite differences in performance during adaptation between 9 conditions, memory decay in a delayed washout block was indistinguishable between conditions. 0Our results thus suggest that, in visuomotor adaptation, sensory predictions errors, but not 1 1 performance errors, update the slow, temporally stable, component of motor memory.

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“…One of the more important uses of motor predictions is in computing sensory prediction errors that are used to guide present and future actions [6, 7]. Many investigators have proposed that sensory prediction errors are the critical error signals for both online control and motor learning [6, 7, 20–24]. …”

Section: Errors Are Critical To the Control Of Movements And Motor Lementioning

confidence: 99%

“…Several of these alternative performance measures have been shown, at least to some degree, to contribute to the control of movement and induce adaptation [32–35]. However, this review focuses on sensory prediction errors because extensive evidence consistently supports their role in motor adaptation and dominance over other types of errors in updating a forward internal model [6, 7, 21, 22, 24, 32, 36]. …”

Section: Errors Are Critical To the Control Of Movements And Motor Lementioning

confidence: 99%

The Errors of Our Ways: Understanding Error Representations in Cerebellar-Dependent Motor Learning

et al. 2015

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The cerebellum is essential for error-driven motor learning and is strongly implicated in detecting and correcting for motor errors. Therefore, elucidating how motor errors are represented in the cerebellum is essential in understanding cerebellar function, in general, and its role in motor learning, in particular. This review examines how motor errors are encoded in the cerebellar cortex in the context of a forward internal model that generates predictions about the upcoming movement and drives learning and adaptation. In this framework, sensory prediction errors, defined as the discrepancy between the predicted consequences of motor commands and the sensory feedback, are crucial for both on-line movement control and motor learning. While many studies support the dominant view that motor errors are encoded in the complex spike discharge of Purkinje cells, others have failed to relate complex spike activity with errors. Given these limitations, we review recent findings in the monkey showing that complex spike modulation is not necessarily required for motor learning or for simple spike adaptation. Also, new results demonstrate that the simple spike discharge provides continuous error signals that both lead and lag the actual movements in time, suggesting errors are encoded as both an internal prediction of motor commands and the actual sensory feedback. These dual error representations have opposing effects on simple spike discharge, consistent with the signals needed to generate sensory prediction errors used to update a forward internal model.

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Visuomotor adaptation needs a validation of prediction error by feedback error

Cited by 27 publications

References 99 publications

Eye-Hand Coordination during Visuomotor Adaptation with Different Rotation Angles: Effects of Terminal Visual Feedback

Eye-Hand Coordination during Visuomotor Adaptation with Different Rotation Angles: Effects of Terminal Visual Feedback

Sensory prediction errors, not performance errors, update memories in visuomotor adaptation

The Errors of Our Ways: Understanding Error Representations in Cerebellar-Dependent Motor Learning

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